Optical node configuration apparatus

ABSTRACT

A segmented optical node exploits a configuration module having arrayed all elements to go from a 1×4 to a 4×4 configuration, save optional redundant switches. A jumper board in the 1×, 2× path configures the node for 1×4 in one orientation and for 2×4 when flipped around 180 degrees. The 4×4 configuration is achieved by rotating the configuration module 90 degrees. In this orientation power to the module is also off, since the 4× configuration is passive.

PRIORITY CLAIM

This application is a continuation-in-part of the application filed with the same name and inventor having Ser. No. 11/677,178, dated Nov. 12, 2012, itself claiming priority to the Provisional Application on file under Ser. No. 61/559,629 filed on Nov. 14, 2011.

FIELD OF THE INVENTION

A configurable optical node, more specifically, a segmented bidirectional node is presented.

BACKGROUND OF THE INVENTION

Cable Operators are continually seeking means to meet the demand placed upon them to provide consumers with more services such as video on demand, Internet access, and voice over internet services. Because the laying of fiber is one of the very high costs incumbent upon a provider, Operators strive to configure networks to satisfy the greatest number of customers through existing fiber by understanding that generally the customers have two distinct needs. First, there are needs for broadcast content such as network television contact where content sent in the forward direction is the same across a broad number of consumers. In the business, this is described as point-to-multipoint services. Generally broadcast services are both analog (extending from Channel 2 at (55 MHz) to Channel 79 (553 MHz)) and digital (extending up to, alternatively 650 MHz or 750 MHz depending upon system design parameters).

For consumers there remains a second type of service known as narrowcast services such as Internet Access, telephony, or video on demand. For these services, known in the industry as multipoint-to-multipoint and carried on spectrum above that of broadcast services generally up to 1 GHz, content is unique on each path and there is no means by which to split and amplify a single signal to reach a large number of consumers. Rather each narrowcast signal is generally a single signal that reaches each consumer distinctly and generally is not split. Return path signals are a special case of narrowcasting in that they are unique signals from the consumer back up to the network headend. Return path signals include video on demand control signals, return Internet data, return telephony data. Return path signals are carried to the headend in frequency bands from 5 MHz to 40 MHz.

Optical nodes facilitate the transmission of data in both directions by serving as the connecting device between the higher capacity fiber optic cable that extends from the headend down to the lower capacity coaxial cable that is generally used to connect individual consumers to the network and carries a signal in that part of the signal spectrum known as radio frequency or RF. In its simplest configuration a conventional optical node is said to be in 1×1 configuration when, it receives one set of downstream content from the headend and transmits just one set of upstream return path signals. (1×1 does not refer to the specific relation between numbers of RF ports used but only to the signal relationship between the node and the headend.) For example, in a broadcast forward mode, an optical signal might enter an optical node having four RF ports for output. In this example, the optical node is in 1×1 configuration meaning that the single downstream signal is split and amplified such that all four ports have the same downstream content and all upstream return signals are combined into a single upstream optical signal. If, in this example, the optical node services a community with 1000 consumer households, each RF port might, if the load was perfectly balanced, carry an RF signal sufficient to serve 250 homes.

Distinct from a 1×1 configuration, a 4×4 configuration can be advantageous. As the name indicates the 4×4 optical node receives for forward distinct optical inputs and returns four distinct optical outputs to the headend. In this example, where four RF ports are present, the optical node converts the optical signals to four distinct electrical radio frequency (RF) signals, which it outputs each to one of the four ports. In essence, the system acts as four distinct optical to RF converters and in the reverse direction as RF to optical converts such that the signals inbound have a one to one relationship with the signals outbound. Thus, using a 4×4 optical node to transmit downstream may be costly in terms of fibers needed to service the network.

Because broadcast service can be carried by fewer optical fibers to serve the same community than is required to service the same community with narrowcast service, operators have found that fully segmentable optical nodes (i.e. those that can be configured to either split or combine signals in traversing between optical and RF ports) have great utility in networks. Operators find it difficult and costly to obtain the rights to place a large number of optical nodes at ground level because, often, many other utility providers must compete for the same space. Thus segmented optical nodes are extremely attractive to operators.

Without disturbing the basic fiber complement extending between a headend and the optical node, operators can install distinct configuration modules to distinctly task both optical interfaces and RF ports and can split signals as needed between them to create distinct configurations for both downstream and upstream signal transmission through the node.

Making an optical node capable to serve several distinct segmentation schemes incorporates very distinct power and hardware requirements. A first basic segmentation scheme is known as a 2×2 requires that a second receiver and a second transmitter be installed in the optical node and a pair of two-way splitters is introduced to replace the four-way splitter between the original single receiver/transmitter and the four RF ports.

In a second basic segmentation known as the 4×4 configuration discussed above, two receivers and two transmitters are added to the two existing receivers and two existing transmitters such that a set of four jumpers is introduced into the system to replace the previous splitter pairs. This 4×4 allows each of a receiver/transmitter pair within the optical node to be commissioned for dedicated service to each of the 4 RF output ports.

Further complications result from the fact that traditional optical nodes rely on passive splitting for the 1×4 and 2×2 configurations, usually combined into a device often known as a configuration module. As these often passive configuration modules have different split losses, the node is designed such that an amplifier is added to supply enough gain between the receiver and RF output section (called a launch amplifier) to overcome the split loss of the 1×4 split. When configure to facilitate the 2×2 split, the optical node now provides excess gain available because exchanging the two-way splitter for the four-way splitter results a lower loss which designers typically address by introduction of a corresponding amount of fixed attenuation. Similarly the loss of splitters in a 4×4 configuration also requires addition of still further attenuation. One consequence of this process is that, as the number of receivers and transmitters increase, the node consumes proportionately more power.

Unfortunately, as can readily be comprehended, each of these distinct modules with their distinct amplification and attenuation as employed in conventional optical node platforms must be separately designed and constructed. Further, the operator electing to reconfigure an optical node must also accommodate unique traffic management configurations, such as dedicating a receiver to 1 port or splitting 2 ports and dedicating a receiver each to the remaining 2 ports. So apart from requiring separate modules for splitting and amplification must also warehouse custom traffic modules. Individuals servicing the nodes are required to warehouse and keep a complete set of distinct modules on hand in order to configure each optical node as the need arises.

What is needed in the art is a readily configurable optical node that allows configuration with a single configurable module which does not require either unnecessary amplification or power loss.

SUMMARY OF THE INVENTION

A segmented optical node exploits a configuration module having arrayed all elements to go from a 1×4 to a 4×4 configuration, save optional redundant switches. A jumper board in the 1×, 2× path configures the node for 1×4 in one orientation and for 2×4 when flipped around 180 degrees. The 4×4 configuration is achieved by rotating the configuration module 90 degrees. In this orientation power to the module is also off, since the 4× configuration is passive.

In its role managing amplification and splitting across the optical node, the configuration module is a “unity gain” device. That is, no matter what configuration, 1×4, 2×2, 4×4, or other, the gain of the module is zero dB. This means that the split loss is overcome in the module itself, and the path configurations are done by a means of an internal jumper board instead of by changing to a new module. In the 4×4 configuration, the module is simply rotated 90 degrees to completely remove power from the module while establishing the required 4 passive RF paths between each receiver and each launch amplifier port.

Because of the unity gain across the module, the module allows conservation of power compared to all other segmentation designs. Because the configuration module is unity gain, the receiver and launch amplifier gain combined can be sized to provide 8 dB less than in a conventional design (8 dB is the rule-of-thumb split loss of a 4-way splitter). The conservation of amplification allows power saving opportunities in the receiver and launch amplifiers by the reduction of gain requirements in those sections.

Further, the configuration module adds segmentation options that have been impractical to introduce into other node designs due to the need to offer such a large number of configuration board options. Those two additional options are 3+1 and 2+2. Additionally, trans-hinge coaxial cables enable a patch panel, allowing the individual servicing the optical node to configure the ports to manage traffic by simple cable arrangement.

BRIEF DESCRIPTION OF THE DRAWINGS

Preferred and alternative examples of the present invention are described in detail below with reference to the following drawings:

FIG. 1 is a block diagram of an inventive optical node with configuration modules;

FIG. 2 is a block diagram depicting the configuration module oriented in a socket at 0°;

FIG. 3 is a block diagram depicting the configuration module oriented in a socket at 90°;

FIG. 4 is a switching diagram depicting the configuration module in a 1×4 configuration with a single jumper board;

FIG. 5 is a modification of the configuration module in a 1×4 with a single jumper board as shown in FIG. 4 to include a redundant relay;

FIG. 6 is a switching diagram depicting the configuration module in a 2×2 configuration with a single jumper board;

FIG. 7 is a switching diagram depicting the configuration module in a 3+1 configuration with a single jumper board;

FIG. 8 is a switching diagram depicting the configuration module in a 2+2 configuration with a single jumper board and a redundant relay; and

FIGS. 9-14 depict various configurations of coaxial patch cords shown to balance traffic at optical transmitters in response to distinct traffic situations.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 is a block diagram of an inventive optical node 10 comprising three distinct and identifiable elements named for their distinct physical locations: a fiber tray 12; a lid 14 containing each of an inventive forward module 147 along with four optical to RF receivers 141 and an inventive reverse traffic manager module 145 and its four RF to optical transmitters 143; and a base 16 having four distinct launch amplifiers 161 a-d and RF ports 163 a-d. Two additional hardline RF ports 165 a, b are included for dedicated power entry but add no additional RF functionality. As set forth, these two hardline RF ports 165 a, b allow for more flexibility in the placement of the power inserter wile alleviating power inserter insertion loss occasioned by relying upon the functional RF ports 163 a-d for power insertion. Two power supplies 149 a, b are present to condition power supplied to the forward 147 and reverse 145 configuration modules.

The fiber tray 12 includes a series of optical connectors 129 for selectively connecting optical fiber to the fiber tray 12 for input and output of optical signals. The arrangement of connectors 129 with the reverse multiplexers 121, 123 and the forward multiplexers 125, 127 allow user configurable selection of optical connectors 129 for suitable configuration in any of the onboard multiplexers to facilitate several alternate configurations allowing the injection of optical signals in distinct configurations depending upon the needs of the operator.

The lid 14 includes, as indicated above, four transmitters 143 and four receivers 141 which together serve as the interface between the optical fiber that ties the connectors 129 to the multiplexers 121-127 and on into the lid 14. The reverse traffic manager module 145 presents the upstream signal to such of its four RF to optical transmitters 143 as it is configured to use to present to the reverse multiplexers 121, 123 for introduction into such fiber optic fibers as are connected to the connectors 129. In a similar manner, downstream signals are received from the forward multiplexers 125, 127 at the receivers 147. The forward multiplexers 125, 127 receive downstream signals through the connectors 129 to convey through such of the four optical to RF receivers 141 as the forward configuration module 147 tasks. Below the discussion moves to treat the operation of the forward 147 and the reverse 145 configuration modules in greater detail than in this overview of the system.

A series of patch cords 15 are configurable to selectively connect the forward 147 and the reverse 145 configuration modules to the several launch amplifiers 161 a-d, through trans-hinge coaxial cables. The trans-hinge coaxial cables allow the user to intuitively connect output of the forward 147 and the reverse 145 configuration modules to such of four launch amplifiers 161 a-d located in the base 16 according to the desired configuration. Simple columnar tables can be included within the base to facilitate the connections necessary.

In the base 16, four bidirectional launch amplifiers 161 a-d are each arranged to condition the signals for the inbound and outbound signals through dedicated RF ports 163 a-d coupled to each of the launch amplifiers 161 a-d. Because these are the principle power consumption devices within the optical node 10, the arrangement of the launch amplifiers 161 a-d, within the base (in the presently preferred embodiment an aluminum casting having heat sink convection fins to dissipate heat generated in signal amplification).

Referring to FIG. 2, the forward control module 147 (and similarly the reverse control module 145) provides conductivity paths or traces from the receivers 141 a-d to the RF ports 163 a-d. Within the module 147, a first set of four traces 1472 extends from a redundant switching section 1471 to a gain and split section 1473 to provide multiple switchably configurable unity gain paths through the module 147. When the module 147 is oriented as depicted in FIG. 2 a first set of pins 1475 engage the socket set 1479 on a base printed circuit board to provide switchably configurable set of four traces through the module 147 appropriate for any but the 4×4 configuration of the module (The 4×4 configuration being enabled by a purely unswitched path through the module (extending from a first set of pins 1477 to a second set of pins 1477, shown) as discussed with reference to FIG. 3 below). In such a manner, the physical configuration of the module 147 with the two sets of pins 1475 and 1477 and two sets of traces connecting those pins are two means to configure the module to present unity gain across the module 147 for each of the configurations in which the module splits and combines signals across the module 147. A user achieves further configuration of the fully configurable module by use of the jumper switch and the gain and split section 1473 as discussed in greater detail below.

In contrast, when oriented as depicted in FIG. 3, a second set of pins 1477 engage the socket 1479 which then connect a second set of traces 1476 for a purely passive path from the first set of pins 1477 to the second set of pins 1477 with no switching capacity needed. As these traces are simple straight and nowhere split along the module 147, they have no need for amplification to make up splitting losses. For that reason, when the orientation of the module is rotated as depicted in FIG. 3 unity gain simply describes conductivity along these traces 1476.

The further innovation that is a key to the versatility of the configuration module is depicted in FIGS. 4-8. By judicious selection and geometric configuration of several elemental components, specifically three splitters 14731 a-c, two amplifiers 14732 a, b (selected to impart gain selected to exactly balance splitter losses), and two redundant relays 14733 a, b, the configuration module can be configured to allow for four distinct configurations in response to positions of a single jumper switch having three positions. The positions for the jumper switch are “1×4”, “3+1”, “2×2” and “2+2”. When the control module configuration module oriented in the socket at 0°, this switch enables tailoring of the module for any of these three modes and with jumper settings, the presence of the redundant relays allows exploitation of second receivers as backups to first receivers providing a failover capacity in the optical node.

By way of overview, each of the several configurations enabled by exploiting a discipline imparted by designing conductivity paths with a unity gain is reviewed in turn. It is an important feature of the configuration block 147 that each configuration, in turn, is achieved by switching the jumper switch and selective connection of components in accord with the switch position. Thus, without other physical change to the configuration block 147, the block yields each of the following configurations: FIG. 4 is a switching diagram depicting the configuration module in a 1×4 configuration with a single jumper board; FIG. 5 is a modification of the configuration module in a 1×4 with a single jumper board as shown in FIG. 4 to include a redundant relay; FIG. 6 is a switching diagram depicting the configuration module in a 2×2 configuration with a single jumper board; FIG. 7 is a switching diagram depicting the configuration module in a 3+1 configuration with a single jumper board; and FIG. 8 is a switching diagram depicting the configuration module in a 2+2 configuration with a single jumper board and a redundant relay.

As is stated above, the user readily configures the module 147 by simply moving the switch from position to position thereby changing the conductive path through the module 147 and its eight elemental components. In this description, only the receiver and forward direction are described. The selection of the forward direction is not meant to limit the configuration block to a single direction. Indeed, the strength of the invention, lies, in part, to its “commutative” nature in that every configuration performed using amplifiers and splitters for forward reception can and is duplicated in the reverse direction for transmission. That the explanation is limited to a single direction is simply that such an explanation is deemed to be adequate to a person having ordinary skill in the art. In a configuration block conforming to the invention it is desirable that both paths are likewise modified by a single movement of the jumper switch or a single change in orientation and in the presently preferred embodiment, both paths are present in a single configuration block though even that is not necessary to practice the invention.

In FIG. 4, the 1×4 forward configuration with no segmentation, wherein one receiver is used. The receiver converts forward optical signal and routes it to the forward configuration module. The forward configuration module then splits the signals into four path and distributes them to each of the four active output ports. As is evident in FIG. 4, the jumper switch is in a first position, specifically the “1×4” position. Once the configuration block 147 is placed in the “1×4” position, a technician connects only one of the four receivers 141 a-d, specifically the first receiver 141 a, with the first amplifier 14732 a and because there is only one, no redundancy is available. FIG. 5 shows the same configuration with the addition of a relay 14733 a and the addition of a second receiver 141 c to allow remote switching in the case of an outage of the first receiver 141 a.

In each of the configurations of the configuration block 147, the conductors are switched to form a path extending from the first and the second amplifiers 14732 a, b which are each configured to amplify the input two-fold to yield an intermediate gain of four times that of the output of receiver 141 a. By switching the two amplifiers to perform in series, unity gain at the output is maintains as the four-fold amplifications to counters the diminution of the signal by the workings of a four-way split of the signal downstream within the block. A first two-for-one splitting occurs at the splitter 14731 c. The output of that splitter is, in turn, split two-for-one at each of a second and a third splitter 14731 a and 14733 b thereby quartering the amplitude conveying the output signal at unity gain relative to the inputs to each of four RF ports.

As stated above, the configuration depicted in FIG. 4 is the same as FIG. 5 except for the relay. In the 1×4 forward configuration with redundancy, one more receiver provides greater reliability increasing the time between maintenance actions. Under normal operation condition, the signal flow is identical to the basic 1×4 forward configuration and the secondary receiver remains as a backup. If the optical power of the primary receivers is below optical power threshold (which can be set by user), it is automatically shut down and the signal is routed to the redundant receiver. The redundant receiver functions the same way the primary receiver does, and when the optical power rises back to suitable levels, the primary receivers 141 a, c are reactivated while the back-ups receiver is shut down.

With the block 147 in 1×4 configuration, the one of the receivers 141 a, b converts the optical input signals to RF signals and then routes them through the forward configuration module. Each signal is amplified by one of the two respective amplifiers 14732 a, b, acting in series to amplify the signal one and again by a factor of two. In either of the configurations depicted in FIGS. 4 and 5, showing the configuration block 147, the conductors are switched to form a path extending from the first and the second amplifiers 14732 a, b to yield an intermediate gain of four times that of the output of receiver 141 a. By placing the two amplifiers in series, unity gain at the outputs is maintained as the four-fold amplifications simply counters the diminution of the signal by the workings of a four-way split of the signal downstream within the block. A first two-for-one splitting occurs at the splitter 14731 c. The output of that splitter is, in turn, split two-for-one at each of a second and a third splitter 14731 a and 14733 b thereby quartering the intermediate amplitude conveying the output signal at unity gain relative to the inputs to each of four RF ports.

In FIG. 6, the configuration block is set, as is apparent, in 2×2 forward segmentation, two of the forward receivers 141 a, c are used as primary receivers while each of two forward receivers 141 b, d wait behind relays 14733 a, b to be activated when necessary as described above in the reference to FIG. 5. Realizing that the placement of the relays and the second receivers 141 c and 141 d to provide redundancy is not necessary for the practice of the invention, the redundancy feature will no longer be repeatedly qualified as an option. In spite of the desirability of redundancy, the invention, as invention, does not require redundant relays and back-up receivers or transmitters to exploit the jumper configurable configuration block and their addition or absence should not be viewed as necessary to practice the invention.

As is the case in the 2×2 configuration the switch in FIG. 6 indicates, each receiver 141 a, b (or individually, as needed, each of their back-up receivers 141 c, d as explained above) is dedicated to two output ports (the first receiver 141 a to 163 a and 163 c and the second receiver 141 b to ports 163 b and d). Upon exiting each of their respective relays, 14733 a, b each of the corresponding amplifiers 14732 a, b amplifies the signal by a factor of two and, at corresponding splitters 14731 a, b, the signals are then split into two paths and distributed to each of two of the output ports 163 a-d for each of the two receivers 141 a, b at an overall unity gain.

Referring now to FIG. 7, the configuration block 147 has been switched into 3+1 Forward Segmentation mode and is shown in a mode with optional redundancy, as explained above. In 2×2 forward segmentation with redundancy, as shown in FIG. 6, four forward receivers 141 a-d are used to supply four ports 163 a-d. In the 3+1 mode, two receivers 141 c and 141 d (changed, in this part of the discussion from 141 a and 141 b to demonstrate the versatility of the inventive configuration block) will supply four output ports. The correspondence, however, is very different. In 3+1 mode, each of the primary receivers 141 c, d are paired with corresponding back-up receivers 141 a, b and one pair, primary 141 a and backup receivers 141 c is dedicated to three output ports 163 a-c, while the remaining pair 141 b, d is dedicated to the last port. (Usually, the one port with the most traffic load.) Also as above, under normal operation condition, the signal flow is identical to 3+1 without the redundancy afforded by the relays 14733 a, b allowing, in each pair, one of the receivers 141 a, b to remain dormant as a backup. Again, if the optical power of one of the primary receivers is below optical power threshold (which can be set by user), the receiver is shut down and the signals are routed to the corresponding redundant receiver. These redundant receivers function the same way the primary receivers do, and when the optical power risks pass, the primary receivers are reactivated while the back-ups are shut down.

Unlike the previously discussed configurations of the configuration block, to achieve unity gain, attenuation gain within the block 147 occasioned by the presence and operation of unpaired splitters, is accomplished by the introduction of two components not operational in the previously discussed configurations. In the 3+1 configuration of the block 147, the output of the first amplifier 14732 a is fed to the first splitter 14731 c. While one side of the output of the first splitter 14731 c is fed to the second splitter 14731 a, just as in the previously discussed configurations, the second side is fed to a pass-through 151 that attenuates the signal by half, thereby providing the RF port 2, 163 b with a signal having unity gain. An attenuator is an electronic device that reduces the power of a signal without appreciably distorting its waveform. An attenuator is effectively the opposite of an amplifier, though the two work by different methods. While an amplifier provides gain, an attenuator provides loss, or gain less than 1.

The pass through functions as an attenuator. Attenuators are usually passive devices made from simple voltage divider networks. Switching between different resistances forms adjustable stepped attenuators and continuously adjustable ones using potentiometers. For higher frequencies precisely matched low voltage standing wave ratio or VSWR resistance networks are used. Fixed attenuators in circuits are used to lower voltage, dissipate power, and to improve impedance matching. In measuring signals, attenuator pads or adaptors are used to lower the amplitude of the signal a known amount to enable measurements, or to protect the measuring device from signal levels that might damage it. Attenuators are also used to ‘match’ impedances by lowering apparent standing wave ratio or SWR.

In an extreme embodiment of an attenuator, a signal or RF trap, dissipates radio frequency energy to eliminate stray currents within the configuration block. All RF energy fed to the signal trap must be dissipated at least within operating frequencies, or it will degrade performance within the configuration block 147. The signal trap 153 performs this attenuation and dissipation of RF energy for the configuration block 147.

With reference to the output of receivers 2 and 4, 141 b and d respectively, the path is identical to that portrayed in either of FIGS. 4 and 5 except that the first output of the third splitter 14731 b that is depicted as flowing into RF port 2 163 b is receiving the output from the pass-through attenuator 151 which attenuates the input signal received at RF port 1 163 b by one half, just as the interposition of a splitter would have done in the same position as the pass through attenuator 151. Just as in the prior configurations of the block 147, the gain across the block at any of the ports remains at unity.

Similarly, the output of the second splitter 14731 b is passed, on the first leg to the fourth port 163 d which receives one half of the RF energy that had been received at the splitter 14731 b input. The other half of the RF energy now is fed into a signal trap 153 that completely attenuates the energy as discussed above and, thus, the signal at RF port 4 163 d arrives with the same unity gain as at its three sisters, ports 1-3 163 a-c.

In the penultimate description, in FIG. 8, the 2+2 configuration of the configuration block 147 is depicted. In the 2+2 forward segmentation configuration, 3 forward receivers 141 a, b, d are used. One receiver 141 a (and its redundant back up 141 c through the relay 14733 a) is dedicated to two of the output ports 163 a, c while each of the remaining two receivers 141 b, d are each dedicated to a single output port 163 b and d respectively. One signal path from the first receiver 141 a is amplified at the amplifier 14732 a and split into two paths at the splitter 14731 a and distributed to two output ports 163 a, c, while the remaining two signal paths emanating from two receivers 141 b, d are directly routed to the remaining two ports 163 b, d individually. Such a configuration is used in the case of heavy traffic loads on two of the four ports 163 b, d.

It is worth noting, at this juncture, there are no physical switches except the configuration switch. In the presently preferred embodiment, positions of the configuration switch selectively activate transistors to provide the actual switching function that the connections portrayed in these drawings. While a physical switch could be used, the present invention can be enabled by either electronic switching or physical switching, but in this depiction the physical switch is used as a valid analogy to portray movement of the signal through the module 147.

FIGS. 10 through 17 depict various patching arrangements that are possible with the coaxial cords used to place the output from the receivers suitably at the inputs of the bidirectional launch amplifiers. Depicted in each is a block diagram of the base 16 having four launch amplifiers 161 a-d and four corresponding RF ports 163 a-d. Each of the four launch amplifiers 161 a-d are bidirectional and will amplify a signal coming upstream or flowing down with a suitable input or output for each as appropriate. Importantly, for clarity, the configuration modules have been removed from the paths for illustrative purposes. To function as discussed herein, however, the configuration modules must be present.

In each of the several depictions, a series of four coaxial jumper cables is shown acting as “patch cords.” A patch cable or patch cord connects (“patches-in”) one electronic device to another for signal routing. Generally, as here, patch cords are used to connect devices of different types (e.g., a switch connected to a computer, or a switch to a router). While the patch cords are numbered 151, 152, 153, and 154, this convention is not meant to suggest that the patch cords, as numbered, are the same cords from figure to figure. Rather, they are numbered simply to locate them for the reader in each of the distinct drawings. The use of all other reference numbers herein are according to the standard convention of identifying the component uniquely and consistently from one figure to the next.

In FIG. 9, two of the four receivers, the first receiver 141 a and the third receiver 141 c, are depicted as connected to individual launch amplifiers 161 a-d, likely to show a broadcast configuration of the device as well as its flexibility. In this example, the north RF ports 163 a, c are experiencing heavy traffic. Assuming that this load is based upon a relatively stable demand such that it is advantageous to configure the optical node to address this demand. An operator can then split the heavier load between two receivers rather than to assign one to the two RF ports 163 a, c, bearing the heavier traffic and one to those ports 163 b, d, bearing the lighter traffic. Thus, an operator would want, optimally, to take the output of Receiver 1 and split it between a heavy and a medium traffic port such as RF ports 1 and 2, 163 a and 163 b. Thus, the operator will connect Receiver 1 141 a to the RF ports 1 and 2, 163 a, b, with coaxial cable patch cords 151 and 153 at the launch amplifiers on the downstream side 161 ar and 161 br respectively. In a similar manner, Receiver 3, 141 c will send its output through patch cords 152 and 154 to the downstream side of launch amplifiers 161 dr and 161 cr respectively. Hence, FIG. 8 depicts the use of the patch cords to suitably address long-term changes in traffic.

FIG. 10 portrays the upstream configuration of the same traffic issues as FIG. 8 portrays. Once again, heavy traffic on RF ports 1 and 3, 161 a and 161 c, dictates a need to balance load as between transmitters 1 and 3, 143 a, and 143 c. To that end, coaxial cables 151 and 153 connect transmitter 1 to each of launch amplifiers 161 ar and br on the upstream side. Again, the transmitter 3 is connected to the upstream sides of launch amplifiers at 161 ct and dt using patch cords 152 and 154 respectively. In this manner, the load on either transmitter 143 a and 143 c is balanced relative to the other.

FIG. 11 shows a situation nearly identical configuration but configured as the coaxial cable is, to split the load between heavy traffic and regular traffic, the split is shown to be advantageous when demand shifts. As can be appreciated, when the heavy traffic has shifted from RF Port 1 163 a to RF Port 2 163 c and likewise from RF Port 3 163 b to RF Port 4 163 d, the exact same coaxial configuration continues to allow a balanced traffic between Transmitter 1 143 a and Transmitter 3 143 c. Given these two depicted examples, one can easily see how even shifting loads can be accommodated by judicious selection of correspondence between transmitters and RF ports.

FIG. 12 shows that traffic has moved to a region that had, in FIGS. 10 and 11 had been served by Transmitter 3 alone. A simple exchanging of the patch cords 151 and as they are connect to input ports 161 bt and 161 ct results in the configuration shown in FIG. 12, thereby returning the balance of traffic as between Transmitter 1 143 a and Transmitter 3 143 c. Clearly any service interruption necessitated by the exchange of the patch cords 152 and 153 will be minimal given the highly intuitive and extremely simple procedure the patch cord arrangement facilitates.

Thus far, we have discussed balanced shifting of traffic such that pairs of ports are experiencing increased or diminished demand. In FIG. 13 a different situation. As discussed in reference to FIGS. 4-8, the configuration module 147 can be configured to a “3+1” configuration just as it can also be configured to a “1×1” with redundancy. Assuming that a service person has suitably adjusted the jumper switches as they are labeled, the output of Transmitter 3, 141 c can be dedicated to a single RF port (RF Port 4 163 d as illustrated) in response to heavy traffic on that single port. The remaining ports can be serviced by the single Transmitter 1 in “3+1” configuration. Coaxial patch cords 151, 152, and 153 connect RF Ports 1, 2, and 3 163 a-c, respectively, to, suitably, balance the traffic between the transmitters.

Again, FIG. 14 demonstrates the versatility of the configuration node 10 as traffic loads shift. In this example, the heavy traffic has shifted from RF port 4 163 d to RF port 3 163 c. Simple exchange of terminal ends of patch cords 152 and 154 results in dedication of Transmitter 3 to the heavy traffic on RF port 3 163 c.

While the preferred embodiment of the invention has been illustrated and described, as noted above, many changes can be made without departing from the spirit and scope of the invention. For example, patch cords may be configured to meet other needs according to the earlier explanation. Accordingly, the scope of the invention is not limited by the disclosure of the preferred embodiment. Instead, the invention should be determined entirely by reference to the claims that follow. 

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:
 1. A segmented optical node comprising: a configuration module including: a switching array for selectively connecting first set of passive traces, splitting, and amplifying elements in segmented traces across arrayed across a base; the first set of passive traces, splitting, and amplifying elements, the passive traces, splitting and amplifying elements being selectively combined to produce configurations in 1×4, 2×4, and 3+1 configurations, the elements including: three splitting or combining elements; two operational amplifiers; and one first passive trace; a second set of four passive traces that when the configuration module is in a second orientation at right angles to a first orientation presents a 4×4 configuration within the configuration module. 